An electron in the ground state of hydrogen atom is revolving in anticlock-wise direction in a circular orbit of radius `R`.
(i) Obtain an experssion for the orbital magnetic dipole moment of the electron.
(ii) The atom is placed in a uniform magnetic induction `vec(B)` such that the plane - normal of the electron - orbit makes an angle of ` 30^(@)` with the magnetic induction . Find the torque experienced by the orbiting electron.

An electron in the ground state of hydrogen atom is revolving in anti-clockwise direction in the circular orbit of radius R as shown in figure. Obtain an expression for the orbital magnetic dipole moment of the electron.

An electron in the ground state of hydrogen atom is revolving in anti-clockwise direction in a circular orbit of radius R. (i) The expression for the orbital magnetic moment of the electrton is (eh)/(n pi m) . Find n square (ii) The atom is placed in a uniform magnetic induction B such that the normal to the plane of electron’s orbit makes an angle of 30^(@) with the magnetic induction. The torque experienced by the orbiting electron is (ehB)/(n pi m) . Find n square

Obtain an experssion for the magnetic dipole moment of a revolving electron.

An electron in the ground state of hydrogen atom is revolving in anticlockwise direction in circular orbit of radius R. The orbital magnetic dipole moment of the electron will be

An electron in the ground state of hydrogen atom is revolving in anticlockwise direction in circular orbit of radius R. The orbital magnetic dipole moment of the electron will be

An electron in the ground state of hydrogen atom is revolving in anti clockwise direction in circular orbit of radius · R'. The orbital magnetic dipole moment of the electron will be

An electron in the ground state of hydrogen atom is revolving in anti-clockwise direction in the circular orbit of radius R as shown in figure. The atom is placed in a uniform magnetic induction B such that the plane normal of the electron orbit makes an angle 30^(@) with the magnetic induction. Find the torque experienced by the orbiting electron.